Cipher checking system



Dec. 21, 1948. M. POTTS I 2,456,733

I CIPHER CHECKING SYSTEM Filed May 27, 1946 3 Sheets-She's: 1

FIG.| Q INVEN TOR LOUIS M.'POTTS, DECEASED MARTHAAW. c.PoTTs,ExEcuTR|x ATTORNEY L. M. POTTS CIPHER CHECKING S YSTEM' 3 Sheets-Sheet 2 Filed May 27, 1946 vm EN pecans 5 M: POT TS Dec. 21, 1948. L. M. POTTS I CIPHER cnscxmc SYSTEM Filed May 27, 1946 v 3 Shets-Sheet 3 INVENTOR LOUIS M. POTTS, DECEASED MARTHA w.c.Po1jTs, EXECUTRIX BY- 2; WM

ATTORNEY Patented Dec. 21, 1948 ICE 2,456,733 CI'PHER CHECKING, SYSTEM Louis M. Potts, deceased by Martha W. C. Pott assignor to Teletype 9 s, executrix, Evanston, Ill., Corporation,

late of Evanston, 111.,

Chicago, 111.,

a corporation of Delaware Application May 27, 1946, Serial No. 672,466

i 3 Claims. (Cl. 17822) This invention relates to secret printing telegraph systems and particularly to a cipher checking system for automatically checking the relative positions of key coding devices at intercommunicating stations.

For secret message transmissions in which key coding means are employed for ciphering operations at each terminal of an intercommunicating system as disclosed, for example, in the copendmg application of L. M. Potts filed October 19. 1942, serial No. 462,522, now Patent No. 2,403,679

issued July 9, 1946, maintaining the key coding at each terminal of the line in devices located synchronism with each other is essential or garbled messages will be printed at the receiving end of the line. In the patent application referred to above, identically coded key tapes are provided at each end of a signal line for ciphering purposes. In such system, unless the key code tape at the receiving station occupies the same relative position as the identically coded key tape at the transmitting station, the cipherin unit at the receiving station will be incapable of de-' ciphering incoming messages inasmuch as the same signal code key tape for the enciphering operation at the transmitting station must also be aiTorded by the key tape of the receiving station for the deciphering operation.

A principal object of the present invention is the provision of a cipher checkin system for determining if the minal of an intercommunicating system are opera ating in phase with each other.

Another object of the invention is the provision of an auxiliary transmitter at the terminals of a telegraph system, each controlled by a ciphering unit for repeating back checking signals to a station of origin.

A further object of the invention is the employment of a signal storage mechanism operable under the control of a ciphering unit for storing checking signals and repeating them back to a station of origin. i

A feature of the invention is the provision of a cipher checking system responsive to a special signal code combination for initiating a checking operation and responsive to another special signal code combination at the conclusion of a cipher checking operation to return the cipher checking system to normal condition.

The principal embodiment of the present invention contemplates the use of identical checking equipment including an auxiliary transmitter at each end of a communication line. Each transmitter will be of the conventional cam controlled type commonly employed in start-stop printing telegraphv similar tothe transm tter shown in Patent No. 1,595 4'72, issued to H. L. Krum, August 10, 1926. Controlof a series of permutation afiorded by the key coding devices of each tertransmitter levers of the auxiliary transmitter is accomplished by means of a series of latches which are further under the control of a series of selector code bars of the ciphering unit. To

initiate a checking operation, an attendant at a local station, for example, will send to a remote station a shift signal followed by an upper case J signal. Upon receipt of the uppercase J signal, the'remote station is conditioned for a checking operation with its keyboard locked up and a signal lamp illuminated, indicatin to an attendant at the remote station that a checking operation is taking place. This conditioning signal is not repeated back to the local station since the system precludes such an operation. Further more, only the auxiliary transmitter at the receiving end of the line is conditioned for operation. The attendant at the local station may now send one or more checking signals, pausing after the transmission of each signal until'the signal is repeated back to the local printer. These checking signals are sent over the line in an enciphered condition by means of the local ciphering unit. Upon receipt of the signals at the remote station the signals are deciphered and printed in plain text and at the same time stored by the auxiliary transmitter. The auxiliary transmitter is subsequently released for operation and the signals are enciphered again in a new signal code permutation afforded by the key tape of the remote ciphering unit which is stepped forward one position each time a signal code combination is transmitted or received. The enciphered signal is received back at the local station where it is deciphered and printed in plain text on the local printer indicating to the local attendant that the respective key tapes are in their correct positions. When it is desired to conclude the cipher checking operation. an upper case "8 signal is transmitted and the cipher checking circuit of the remote station is returned to normal. It is to be understood that if there is an indication that the positions of the key tape of the local and distant station do not correspond, proper steps will be taken to remedy this condition.

A modified form ofthe invention also prov des at each end of'the line an auxiliary cam controlled transmitter and. in addition t re ut lizes a special switching means co tro l by a cam driven at half the speed of normal transmission. This cam, during the first half of its rotational cycle, places the local printer incircuit for receiving a signal and in its second half of its cycle places the auxiliary transmitter in c rcuit for a repeating back operation. The auxiliary transmitter is released for operation in both portions of this cyc e but is only cond tioned in the last half of the cycle for the repeat ng back operation.

"A second modification of the invention features attendant thereat that the key tapes are core 1 signal code combination which rectly positioned for a ciphering operation. The

conditioning of both a local station, or'stations originating a checking operation, and a remotestation for the transmission back of the upper case S signal code combination is accomplished by first sending the shift signal followed by an upper case J signal. The conditioning operation effects the illumination of signal lamps at both stations which are later extinguished upon receipt of the uppercase S signal. It would be good practice to repeat this checking operation several times since there is a possibility that a false uppercase "8 signal might be repeated back as it is conceivable that the key tape at the remote station might accidentally present a signal code combination capable of.

deciphering upper case J just at this particular time and still be improperly placed. in the ciphering unit. Receipt of the upper case S signal by the printer at the remote station through its own local circuit and at the local station over the line is effective to return both cipher check ng units to normal and extinguish the signal lamps.

The invention may be more readily comprehended by reference to the following detailed description and the accompanying drawings wherein: a

Fig. 1 is a schematic circuit illustration of the.

principal embodiment of the invention;

Fig. 2 is a schematic circuit illustration of the first modification of the invention; and

Fig. 3 is a schematic circuit illustration ofthe second modification of the invention.

With reference now to Fig. 1 of the drawings, a description of the principal embodiment of the invention will proceed. It will beunderstood that the present invention could. be conveniently incorporated into the mechanical cipher-ing systern v disclosed in the copending application of L. M. Potts, hereinbeiore mentioned and refer-v ence thereto should be made for a detailed. description of the ciphering system. The direction switch indicated generally as I in Fig. l is equivalent to the similarly numbered direction switch I00 disclosed in the Potts application. Likewise, switch 235. which, in its upward position, is conditioned for normalv transmission and in its lower position for. ciphering transmission, is similarly numbered as. is the pivoted regenerative repeater contact H8, the selector magnet 6.4. and, thestart magnet 65;. The ciphering and checking equipment ateach terminal of the line are. of identical construction and for the. purposes of description are presumed to be similarly numbered although no details of the equipment at the distant stationare actually shown in the drawing. a

When an attendant at the local transmitting station indicated generally as. numeral desires to send ciphering, signals in accordance with a predetermined arrangement with an at-. tendant. at a distant station III, switch 235 is placed in its downward position which places selector magnet 64 through the direction switch I00, normally in its leftward position, in circuit with the local transmitter l2 and a repeating relay l3 which controls the printer selectormagnet 9 over the following circuit: irom positive lead Hi, through contact pair l5 of the direction switch I00, over conductors it and H, through the winding of selector magnet 64, over conductors l8 and I9, through contact pair 20 of direction switch I00, over conductor 2 I, through con- 1 tact 22 of switch 235, over conductor 2.3 through transmitter l2 and repeating relay l3, over conductor 24, through contact 25 of an auxiliary transmitter indicated generally as 26, over conductors 2? and 28 and through contact 29 of switch 235tothe negative lead 3 l.

When direction switch I08 is automatically positioned in its rightward or receiving position for receiving an enciphered signal from a distant station ll, start magnet 05 and regenerative repeater'contact i i8 are taken out of a loop circuit extending from distant station H and placed in the circuit just described above. At the same time, selector magnet 64 is removed from the just described circuit and placed in the loop circuit to station l I. With the switch 100 in its rightward or receiving position, conductors hi and 21 are connected respectively through con tact pairs 32 and 33 to conductors 3 5 and 35 toythereby establish the start magnet and regenerator repeater contact H8 in the local circuit which formerly included selector magnet The loop circuit mentioned above for start magnet 65 and regenerative repeater contact H8 with direction switch I00 in its leftward or transmitting position is traceable as follows: From distant station H, over loop line 36, through contact 31 of switch 235, over conductor 38, through, contact pair- 39- of the direction switch H00, over conductor 35, through the winding of start magnet 65,, through regenerative repeater contact H8, over conductor 30, through contact pair 4| of the direction switch l00, over conductor 42 and through contact 43 of switch 235 to the loop. line 44 and distant station H.

When the direction switch I00 is automatically moved to its rightward position for receiving enciphered signals, contact pairs E5 and 56 of the direction switch are closed, thereby placing selector magnet 64 in the loop circuit. to distant station H just described above, over conductors ll, and i8, respectively. Start magnet t5 and regenerative repeater contact H8 are at this time taken out of the loop circuit when the direction switch Hillis moved to its rightward or receiving position as previously explained and placed in circuit with. the local transmitter l2 and receiving relay i3 which controls printing selector magnet 9.

Details of operation of the automatically controlled direction switch Hill, fully described in the Potts application referred to above, will not be enumerated, it being sufiicient to state, that normally direction switch I00 is biased in its leftward or transmittin position, that the receipt of a start signal by the selector magnet as indicating a transmitting or enciphering operation is to take place will enable direction switch I00 to remain in itsleftward position and that on the other hand, receipt of a start signal from the loop line 36, M extending from the remote station- 5 l, by the start magnet 65, indicates that enciphered signals are to be received and direction switch I00 i automatically moved to its rightward or receiving position.

The ciphering unit includes a series of five code bars. 47, only one of which, is shown in the drawing, and a start bar and stop bar, neither of whichisshown. The code bars 41 are under the operated at the end joint control of a key code tape feeler mechanism not shown which governs the lateral position of the code bars and the selector magnet 54 which through the position of itsarmature 48 cooperates with the tape feeler mechanism to determine ultimately, by the position of notch 50 of the code bars with respect of armature 48,-whether the code bars 41 will be tilted in a clockwise or a counterclockwise direction' as viewed in Fig. 1 to accordingly sequentially operate the regenerative repeater contact H8 to either its spacing or marking position. The start bar is universally operated at the start of a signal code permutation to place the regenerative repeater contact H8 in its spacing or no current position while the stop bar is universally of a signal code permutation to place regenerative repeater contact H8 in its marking or current position.

' When an attendant at the local station 19 wishes to determineif the position of the key code tape at the remote station II corresponds with the position of the key code tape at the local station 10, manual switch 49 will be opened at the local station. The attendant will then send a shift signal to condition the receiver at the remote station H for the next following signal to be transmitted, which is the upper case J signal; Receipt of the upper case J signal at the remote station ll effects the closure of its contact pair due to theselection of the upper case J pull bar 52 thereby energizing conditioning relay 53 over the following circuit: From positive lead 54, through the winding of conditioning relay 53, over conductor 55, through closed contact pair 5|, and through manual switch 49 to ground. This causes relay 53 to attract its armatures 58, 51, and 58. Conditioning relay 53 becomes locked up overthe following circuit: From positive lead 54, through the winding of relay 53, through the contactof armature 58, over conduCtOr 59, through the contact of armature 61 of relay 62 to ground. Closure of the contact associated with armature 51 of relay 53 provides an obvious circuit for signal lamp 83which lights up, indicating to the attendant at the remote station that a checking operation is taking place. Operation of armature 51 of relay 53 further provides the following circuit for a keyboard looking relay 61: From ground, through the contact of armature 51, over conductors 68 and 69, through the winding of relay 61, over conductor 1| to positive lead. 54. Keyboard lockingmagnet 61 now attractsits armature 12 which looks the keyboard at the'transmitter at the distant station by blocking universal bail 48. membered that the local station is unafiectedby the transmission of the upper case J signal since manual switch 49 thereat was' opened at the'start of the checking operation.

The attraction of the armature 56 of conditioningrelay 53 through its front contact prepares a circuit for clutch magnet which controls the rotary movement of a cam sleeve 13 of the auxiliary transmitter 26in a manner well knownin the printin telegraph art, through the expediency of a single revolution clutch. This circuit is established as follows: From ground, through through contact 16, through con It will be re to positive lead 54. Contact'15 iscontrolled by a cam 19 mounted on a cam sleeve 8 I of the cipherto the position of the free end ing unit at the remote station, details of which are not shown in the present invention. However, cam sleeve 8| is equivalent to the cam sleeve 41 disclosed in the Potts application mentioned above.

When a checkin operation is not taking place, a magnet 82 is normally energized and is effective to block the selection of gooseneck transmitting levers 85 of the auxiliary transmitter 26. Further, since upper case J signal is received, this signal is not stored at the distant station. The operating circuit for magnet 82 is provided over positive lead 54, through the winding of magnet 82, over conductor 83 and over back contact of armature- 56 to ground. Magnet 82, when energized, urges its blocking armature or bail 84 in a counterclockwise direction against the action of spring 90, holding the gooseneck levers 85 at their depending portion 86 from movement during receipt of the upper case J signal, After the receipt of upper case J signal, the circuit of magnet 82 is broken due to the operation of armature 58 of conditioning relay 53, and the transmitter .gooseneck levers 85 are free for further selections as will appear immediately hereinafter.

As selected ones of code bars 41 of the ciphering unit are tilted in a counterclockwise direction to provide a marking impulse by means of regenerative repeater contact H8, associated latches 81, having hooked extensions and nor- 'mally urged in a counterclockwise direction by springs 88, are now moved in a clockwise direction due to the superior force exerted by associe ated code bars 41. This frees associated goose"- neck levers at their lateral extension 89 for partial pivotal movement in a counterclockwfie direction due to the fiexure of contact springs 9| of transmitting contacts 92. When this occurs, projections 93 of selected ones of the gooseneck the cams to permit the closure of contacts 92 at this time. Later in the operation, however,'the projections 93 will drop into the notches 95 as cam sleeve 13 is released for rotation, thereby closing selected contacts 92 to send marking impulses to selector magnet 64. After projections 93 fall into notches 95 of the cams 94 during their rotation, they ride upon the high parts 91 of the cam in proper timing to reset latches 81 for receipt of the next signal code combination.

Following the transmission of upper case J signal, the local attendant will send one or more checking signals and upon receipt of the first checking signal, repeating relay 13 at the distant station will repeat to printer relay 9 the selected character permutation codes in deciphered form. The incoming signal having been deciphered at this time with direction switch I in its rightward or receiving position and the code bars 41- of the ciphering selector operated, the identical code combination repeated through the regenerative repeater contact stored by means of the latches 81 in the transmitter 25 as explained above.

been deciphered, cam 19 carriedby sleeve 8| 1S timed to close momentarily contact 15, thereby completing the previously described circuit for clutch magnet 19. Upon enmagnet 82 is energized until the- H8 is also transferred and ergization, clutch magnet I attracts its armaturev 53, thereby withdrawing it from projection 98: of a. driven portion of' a single revolution clutch,. permittinga single revolution of cam. sleeve I3 which carries the set of transmitting cams 94- of theauxiliary transmitter 26;

Upon; release of cam sleeve 13, the gooseneck lever at the: extreme left will invariably open its start stop transmitting contact 25 to send a start or spacing impulse thereby placing direction switch H33 in its leftward-ortransmitting. position through a circuit provided over. conductors-24 and 21, described. in detail in an'earlier'pa-rt of the specification. The gooseneck levers 85' selected during the enciphering operation willv fall into notches 95 of associatedxcams 94', closing contacts 92'to send marking or. current. impulses to selector magnet 64. Unselected gooseneck levers 85' will retain associated contacts 92 in their open position, sending spacing. or no current impulses toselector magnet 64. At the'endof a single revolutionof cam sleeve 13,: contact 25 will close in the rest" position andpwill invariably send a marking impulse to selector magnet 64. Since direction'switch I00 is in its leftward position: during a transmitting; operation; contact pair I1 is open, thereby precluding a repeat operation of clutch magnet III by breaking its circuit; The resetting oflatches 81' through parts 91 of. the transmitting cams 94 is timed so that movement of the code bars 41 in a counterclockwise direction during a repeating back operation is: ineffective tocause rest'orageiof the signal by latches 31.

' It will now be'seen'that an encipheredchecking signal has been transmitted-by the local station lll tothe remote station IIwhere thesignaliwas deciphered and enciphered again, due to the fact that thekey tape in the ciphering unit is advanced one position for each signal codecombination; and repeated'back'tothe local station whereit was again decipheredand printed in plain text. The attendant at the-local station may send'additional checking signals if. it is desirable from an operating standpoint to insure the correct positionv of the key tape After the checking signalor signals are transmitted, the local at tendant will send an upper case "S signal which results in the closure of contact pair 99 by upper case S pull bar. Ill-I at the remote station II, thereby energizing relay 62 over an obvious circuit, andlbreaking the locking circuit ofthe conditioning relay 53 afforded through armature 6| of relay- 62,,which brings the ciphered checking circuit .back .to' its original condition. At this time, signallamp 53 is extinguished and keyboard locking lever I2 is released. If the attendant. at the remote station desires to communicate with the local station in an emergency while a checking operation is proceeding, a special) key I02 is depressed, energizing relay 62 to likewise bring. the-checking circuit back to normalcondition. If. there is an indication that the key tape at the remote station is not-in the same relative position as the key tape at the local station, proper. steps will be taken. to place the tapes in phase for future ciphering operations. For instance, a slow to release relay could be placed inthe line circuit which would be de-energizedupon: a. complete break of the line circuit to. thereby cause the operation of a circuit for a. special, signal bell or lamp.

The-first modification of the invention (Fig. 2)

now, to be described. relies-also on reference to the to selector magnet 64" the control afforded by high to the similarly numbered direction switch IIIIJ disclosed in the Potts application. Switch 235 is likewisenumbered as is the-regenerative repeater contact M8,. the selector magnet 64 and the start magnet 65.

The normal transmitting circuit for local station III, when sending enciphered signals is as follows: From positive lead IIil, over conductor II3, through contact I30, over conductor I I5, through selector magnet 64, over conductor H6, through contact pair N1 of direction switch Hill, over conductor 228, through contact N9 of switch 235, over conductors I2I and I20, through the back contact of armature I22 of conditioning relay I23, over conductor I24, back through the printer selector magnet I2'I, through the transmitter I28, over conductor I23 and through contact I3I of switch 235 to negative lead I32. net 65 and regenerative repeater contact I I8 are in circuit over a loop line extending to the distant station H2 as follows: From loop line I33 through contact I34 of switch 235, over conductor I35, through contact pair I36 of direction switch I03, over conductor I31, through the winding of start magnet 65, over conductor I38, through regenerative repeater contact II8, over conductors I39 and I'M, through contact pair I42 of direction switch IlIIl, over conductor I43 and through contact I44 of switch 235 to the other side of the loop line I45.

Positioning of the direction switch I00: in its rightward or deciphering position for the receipt of a message, closes contact pairs I46" and I41, placing selector magnet 64- in the loop circuit by connecting conductor I I5withconductor by connectingconductor I16 with conductor I35. The simultaneous closing of contact pairs I48 and I49 ofthe direction switch I00 connects conductor II3 with conductor I39 and connects conductor 228 with conductor I31, thus placing'start' magnet 55 and regenerative repeater contact H8 in the previously described circuit with the printing magnet I2'I.

Before the description of a typical checking operation is commenced, it will be again presumed as in the principal embodiment of the invention that the local and remote stations are equipped with identical ciphering and checking units and that the numerals used in thedescription are identical for both stations despite the fact that only the equipment at the local station is actually disclosed in Fig. 2,

When the attendant at local station II2 desires to check the relative positions of the key tapes at the local and remote stations, the manual switch 248 is opened breaking a circuit extending through contact pair I54-controlled by upper case J pull bar I55. This will prevent conditioning of the checking system at the local station as will immediately hereafter be evident since it is not desired that the station originating the checking operation be conditioned.

The local attendant will now send a shift signal to the remote station II2 followed by an upper case through contact pair the uppercase J tioning'effect at the local station. At the remote station H2, however, the receipt of the" upper case J signal will cause the selection of upper: case J pull bar I55 and closure of con- I54' is open at this time,

pair H4 of direction switch At this time start mag- I43 and.

J signal and since the circuitsignal will have no condi tact pair I54 which I I55, through the rear As armature I22 of place, as follows: From associated contact it relay .through the winding of relay I 8|;

I84, through contact I 82 when movesfrom its back contact to its-front contact, it breaks the previously-described circuit for the transmitter I28 and places it in a circuit traceable through a normally closedstart-stop contact .163 of an auxiliary: transmitter indicated: generally as I64 as follows: From the previous transmitting circuit extending over conductor I21, over conductor I65, through closed contact I63, over conductors I66 and I61,through the front contact ofarmature tor. I24 to thepreviously tending to conductor I29.

Attraction of armature lay- I23 closes a circuit for described circuit ex- I68 by conditioning relighting a signallamp I69 to indicate to 'the'attendant at the remote station H2 that archecking operation is taking positive lead H8, over conductor H3, through signal lamp I69, over conductor I 51, through closed contact of armature I68 and over conductor I12to negative lead I I 58.. I r a 7 As armature I 13 'of relay I23 moves from its breaks a circuit for normally energizedrelay I14 which formerly was -as follows: From positive lead II8,"over conducoverconduct'orl15, through the winding I13, and over conductors lead I58. The purpose of I14 similar to the relay 82 described in the I85 and I51 to negative mal ciphering operations.

. The ciphering unit at the remote station restart bar I18 over thefollowing circuit: from positive lead IIO,.ove'r the conductors II3 and I48, over conductor over conductor closed, and over and I 51 to negative lead I 58.

I83, "through closed contact I19,

conductors I85 I "The single revolution clutch controlled by clutch magnet I81 is normally restrained from operation by armature leve'r5I86 which is biased in a counterclockwise direction by a spring "I81 conditioning relay I23 I22 and over conducfor a single revolution of'the sleeve I9I. periphery of switching cam I92 is have'approximately half of its follower surface 'follower surface present a low portion -follower I96 which is urged into contact with the peripheryof'the cam by means of a spring I91.

.oneslbf thecode bars I11 unlatch operation and thus "cause the storageof the incoming signal.

I89 and" thereby releases "and which engages at its outer end projection I88 of cam I89 fixedly secured to a driven cam. sleeve I 9I of the clutch assembly. Also carried by sleeve I.9I is a switching cam I92 and a gear I93. Meshing withgear I93 is a relatively smaller gear I94 which is'dr'iven' at a two to one ratio so that a shaft I95 secured thereto makes two revolutions The designed to present a highportion and the other half of its to a switch deciphering of the upper signal by the remote station, selected transmitting gooseneck levers I98 due to the tilting of latches I99 in a clockwise direction, while unselected gooseneck levers I98 remain latched up, depending upon the particular signal code combination beingdeciphered. However, normally magnet I14 remains energized and through the engagement of blocking armature or bail 28I with the dependingportion 280 of the gooseneck levers prevents blocks the storage of the upper case fJisigna1 at the distant station. Latches normally urged in a I engaging the edges of the selector I11. The vertical portion of the latches of incoming upper case:.J signal, the latches I99 are ineffective to e'ver,.further signals maybe stored due to the subsequent de-energization of magnet I14 and .releas'eof blocking armature 20I by spring I50. After start bar I18 is operated on receipt I 82 doses and is effective to complete the circuit .for the energization of the clutch magnet I8I.

Energization of magnet I8I removes the armature I 86 from the path of the projection I88 of cam cam shaft I for two revolutions, through releasingsleeve ISI for one revolution. During the first half revolution of switching cam I92, the transmitting contacts I63 of the auxiliary transmitter are shunted out of the transmitting circuit due to the closure of con- The auxiliary transmitter I64 is thus placed in series with thetransmitter I28 over the conductor I24. Asswitch 285 checking operation.-

Since magnet I14 'remains energized as explained and since clutch magnet I8I is not energi'zed'uiitilthe'first checking signalfollowing upwhich engages the lateral .portion 283 ofthe levers I98. As stated before. during the receipt c rried by the driven 11 per case J, through closure of contact pair l82iby start her |-'I8,.shaft I95 of transmitter IN is released for .the .firsttime upon receipt .ofthe first actual checking signal. Selected \gooseneck levers l98 .through operation of certainselected code bars [11 at their projections 201 fall linto notches 208 of associated transmitting cams-2.25 as they rotate in the conventional manner. .Although shaft I95 is. released, transmission of the checking signals does not2take place until its-second revolution with contact pair Zilli opened by switch 205. The local operator can thus send additional checking signals pausing each time until a particular signal .is repeatedback. After the transmission of upper case .J.by the local operator it would be good practice to pause .momental'ily to insure that .the distant station is conditioned before sending the first checking 'signal, These signals willbe deciphered at the distant station and again enciphered and repeated back as contact 206 of switch 205 is opened at the mmencementof the second revolution of cam shaft I95 when the auxiliary transmitter IE4 is placed the transmitting circuit.

For the resettin Of levers I98 to normal position held by the latches L99 a bail I08 is provided, o erable y hi h part 209 of a' am sleeve l9 l which also carries the cam il-lz'and gear I 93. This operation will be p o er t m d n a the e d of a single evolution of cam. 12M or two revolutions of cam shaft 155. Ball IE8 is pivoted onrod 1212 and its arm 213 is urged into contact with the periphery of a ill by spring 214 and as arm vl 13 engages he-high par 226 of the cam tension 21-5 of bail W8 engages the depending portions 200 of selected gooseneck levers I98 to move them a sufiicient distance in a clockwise direction to become latched up once moreby the latches I99.

Alter the checking operation is completed, the local attendant will send an upper case S? signal which causes the upper case S pull bar 2|] to be selected at the distant station whicholoses contact 2H3 thereby establishing. an energizing circuit for relay Hi2 as follows: .from positive lead ill} over conductors H3 and 219, through the windin o relay I62, through closed contact H8 and over conductor ll to ne ative lead I58.

As a result, armature I61 is attracted by relay I83 breaking the, locking circuit for relay 123 and the cipher checking circuit. is returned to norm condition with lamp [69 extinguished, magnet Ht energized and keyboard locking lever released. In the event that there isindication of the improper positioning of the keytapes, steps will be taken to place the tapes in their proper position for further ciphering operation.

The second modification of the invention is shown in Fig. 3 and also relies upon the aforementioned Potts application to supply details of the cipher system. Direction switch I00, switch 235, selector magnet 64, start magnet 65 and a regenerative repeater contact H8 are numbered similarly to like parts in the Potts application. It is further understood that in this modification identical cipher checking equipment is provided at each end of the line similarly numbered, al.- though only the cipher system at the local station is completely shown.

In this embodiment of the invention, when the local attendant desires to check the relative position of the key tape at the local station 3H! with the position .of the identical key tape of dis.-

21 l the lateral exover conductor .221, v

the loca station am causes tantstation 1312, a shift signal is vfirst transmitted. The upper case 'IJ .key :3l3-is next depressed closin -contact 3M and causing the immediate=energization of relaya I 5 at the local station prior to theclosure of contact 3|.6 by the upper case J null bar .311 as follows: From ositive lead .318, through the winding of relay '8l5, over conductor All) and through closed contact M4 to negative lead-309; Relay 3l5 now .be-

comes locked up over the following circuit: From positive lead .3118, through the winding of relay 3| 5, throu h closed contactoi armature .31 9, over conductor .321 and throu h normally closed contact 322 controlled by upper case S, pull bar .323 to nega ive lead 324. .At the same time a signal lan p-fi2i warn n the distant operator of a oh tking-roneration,.is lighted due to the :attraction :oi armature 326-by1re1ay 3I5 y means of current flowing over the following path: From power lead v321, through the contact of armaturefiZB, over conductor 328 and through signal 18111115325. to power lead 329. Subsequent closure of contact -3-l8 by. the upper case .J pull bar 31"! :atwthe' local station is ineffective to energize r lutehma net .33l over conductor 332, due to the negative condition of the circuit at armature 3l9 of relay 3l5.

However, at the distant station, y l3 wi not be operated and contacts 314 will therefore not close; Thus, when the upper case 'J pull her .3211 is selected, an energizing circuit is :made im in! clutch magnet .33! and .for relay 315 over the following-path: from positive .lead 318, through the windings of relay 315 and clutch magnet. 33!, over conductor 332 and through closed contacts 3H5 to negative lead 324. Relay 31 is locked up and signal lamp 325 is lighted at the distant station in the same. manner as at he local station.

.llner igati no -cllltoh'magnet :33! at the distant station 312 causes the operation of a conventional single revolution clutch indicated genorally at dilfi dueto the attraction of armature 3. ;4 bY-th '1l h magnet v33L Mounted on the drivensleeve 335 of the clutch is a coded transmit in fi am disc 33B, specially notched in the a, signal code combination which is Nos. 1 and .3 impulsesmarking, and Nos. 2, 4, and 5 impulses spacing. Releaseuoidriven sleeve 335 for ingl revolution causes therefore the p ation of the transmitting cam disc .336 in accordanoe with the 5" signal code combination to ake and break the. circuit controlled :by transmitting oontaottfi. Transmittingcontact .331 is n ircuit with the transmitter .338 at the dis tan s ation 312 over conductors 341 and en. The transmittin and receiving circuit of the eiphering system and operation of direction switch 199 have been .fully explained in the prin- @984 ahd'first modification of the present inven i n. I I

When the. upper case 8" signal is received locally bytheiprinter magnet i589 in plain text .at distant station, upper case S pull bar 323 will be selected and will open .the contacts 3 This w ll. return the distant station :to'normal by breaklngthe looking circuit of relayalfi, thereby -extin ui hingnsignal' lamp 325 thereat. At the same time the, 3" signal isenci'phered by the cipharing unit and transmitted through operation of regenerative, repeater contact H8 to the local station iilO... Receipt of the enciphcre u per case 8 si nal andits decipherin at theselection' of its "upp r-ceas 3" null-bar 3.23 and opening of its contact 322 to return the local station to normal as was done at the distant station. This is due to the breaking of the locking circuit for relay 3l5 which extinguishes signal lamp 325, indicating to the local operator that the key tapes at both places are synchronized. In case the key tape at the distant station Was accidentally in a position to correctly encipher the upper case J signal, repeat checking operations may be made to verify the correct position of key tape.

Although it is conceivable that in the principal and modified forms of the invention the cipher checking system may be successfully operated with a checking unit at one line terminal only, cipher checking units have been disclosed at both terminals. In the description particular signal code combinations have been used only for the purposes of illustrating the invention and obviously other signal code combinations could be used. Various changes and modifications may be made in the present invention without departing from the spirit or scope thereof.

What is claimed is:

1. In a secret message transmission system, the combination ofa first station, a second station, a communication channel associating said stations, means at said first station for selecting variable code combinations of impulses for transmission over said channel, ciphering means operating step by step in accordance with the operation of said selecting means to encipher said selected code combinations, means at said second station for receiving successive enciphered code combinations, deciphering means operative step by step in accordance with the operation of said receiving means to decipher said received code combinations, and means for checking Whether the cipherin and deciphering means are in phase comprisin a. transmitter at said second station inoperative during normal transmission and reception, means responsive to a special code combination transmitted by said first station, enciphered by said ciphering means, received at said second station, and deciphered by said deciphering means to condition said transmitter for operation, means operated by a subsequent enciphered code combination transmitted from said first station and deciphered at said second station for storing the deciphered code combina tion in the conditioned ing said transmitter to transmit the deciphered code combination enciphered by said deciphering means to said first station to be deciphered thereat by said ciphering means, whereby the proper reception of said dicative of the proper phase relationship between said ciphering and deciphering means, and means operative by another code combination to restore said transmitter to normal inoperative condition.

2. In a secret message transmission system, the combination of a first station, a second station, a communication channel associating said stations, means at said first station for selecting variable code combinations of impulses for transmission over said channel, ciphering means operating step by step in accordance with the operation of said selecting means to encipher said selected code combinations, means at said second station for receiving successive enciphered code combinations, deciphering means operative step by step in accordance with the operation of said receivtransmitter and for causcode combination is inr is indicative of the proper phase relationship between said ciphering and deciphering means, and means operative to restore said transmitter to normal inoperative condition.

3. In a secret message transmission system, the combination erating step by step in accordance with the operation of operative step by step in accordance with the operation of said receiving means to decipher said received code combinations, and means for checking whether station inoperative during normal transmission and reception, means responsive to a special code combination transmitted by said first station, enciphered by said ciphering means, received at said second station, and deciphered by said deciphering means to condition said transmitter for operation, and means operable upon the conditionment of said transmitter to cause said transmitter to automatically transmit a deciphered code combination enciphered by said REFERENCES CITED The following references are of record in the file of this patent:

UNITED STATES PATENTS Number Name Date 1,310,719 Vernam July 22, 1919 2,003,325 Watson June 4, 1935 2,281,745 Buckingham May 5, 1942 2,354,534 Mason July 25, 1944 2,405,571 Fitch et a1 Aug. 13, 1946 

